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AbstractQueuedSynchronizer Class

Definition

Provides a framework for implementing blocking locks and related synchronizers (semaphores, events, etc) that rely on first-in-first-out (FIFO) wait queues.

[Android.Runtime.Register("java/util/concurrent/locks/AbstractQueuedSynchronizer", DoNotGenerateAcw=true)]
public abstract class AbstractQueuedSynchronizer : Java.Util.Concurrent.Locks.AbstractOwnableSynchronizer, IDisposable, Java.Interop.IJavaPeerable
[<Android.Runtime.Register("java/util/concurrent/locks/AbstractQueuedSynchronizer", DoNotGenerateAcw=true)>]
type AbstractQueuedSynchronizer = class
    inherit AbstractOwnableSynchronizer
    interface ISerializable
    interface IJavaObject
    interface IDisposable
    interface IJavaPeerable
Inheritance
AbstractQueuedSynchronizer
Attributes
Implements

Remarks

Provides a framework for implementing blocking locks and related synchronizers (semaphores, events, etc) that rely on first-in-first-out (FIFO) wait queues. This class is designed to be a useful basis for most kinds of synchronizers that rely on a single atomic int value to represent state. Subclasses must define the protected methods that change this state, and which define what that state means in terms of this object being acquired or released. Given these, the other methods in this class carry out all queuing and blocking mechanics. Subclasses can maintain other state fields, but only the atomically updated int value manipulated using methods #getState, #setState and #compareAndSetState is tracked with respect to synchronization.

Subclasses should be defined as non-public internal helper classes that are used to implement the synchronization properties of their enclosing class. Class AbstractQueuedSynchronizer does not implement any synchronization interface. Instead it defines methods such as #acquireInterruptibly that can be invoked as appropriate by concrete locks and related synchronizers to implement their public methods.

This class supports either or both a default <em>exclusive</em> mode and a <em>shared</em> mode. When acquired in exclusive mode, attempted acquires by other threads cannot succeed. Shared mode acquires by multiple threads may (but need not) succeed. This class does not &quot;understand&quot; these differences except in the mechanical sense that when a shared mode acquire succeeds, the next waiting thread (if one exists) must also determine whether it can acquire as well. Threads waiting in the different modes share the same FIFO queue. Usually, implementation subclasses support only one of these modes, but both can come into play for example in a ReadWriteLock. Subclasses that support only exclusive or only shared modes need not define the methods supporting the unused mode.

This class defines a nested ConditionObject class that can be used as a Condition implementation by subclasses supporting exclusive mode for which method #isHeldExclusively reports whether synchronization is exclusively held with respect to the current thread, method #release invoked with the current #getState value fully releases this object, and #acquire, given this saved state value, eventually restores this object to its previous acquired state. No AbstractQueuedSynchronizer method otherwise creates such a condition, so if this constraint cannot be met, do not use it. The behavior of ConditionObject depends of course on the semantics of its synchronizer implementation.

This class provides inspection, instrumentation, and monitoring methods for the internal queue, as well as similar methods for condition objects. These can be exported as desired into classes using an AbstractQueuedSynchronizer for their synchronization mechanics.

Serialization of this class stores only the underlying atomic integer maintaining state, so deserialized objects have empty thread queues. Typical subclasses requiring serializability will define a readObject method that restores this to a known initial state upon deserialization.

<h2>Usage</h2>

To use this class as the basis of a synchronizer, redefine the following methods, as applicable, by inspecting and/or modifying the synchronization state using #getState, #setState and/or #compareAndSetState:

<ul> <li>#tryAcquire<li>#tryRelease<li>#tryAcquireShared<li>#tryReleaseShared<li>#isHeldExclusively</ul>

Each of these methods by default throws UnsupportedOperationException. Implementations of these methods must be internally thread-safe, and should in general be short and not block. Defining these methods is the <em>only</em> supported means of using this class. All other methods are declared final because they cannot be independently varied.

You may also find the inherited methods from AbstractOwnableSynchronizer useful to keep track of the thread owning an exclusive synchronizer. You are encouraged to use them -- this enables monitoring and diagnostic tools to assist users in determining which threads hold locks.

Even though this class is based on an internal FIFO queue, it does not automatically enforce FIFO acquisition policies. The core of exclusive synchronization takes the form:

<em>Acquire:</em>
                while (!tryAcquire(arg)) {
<em>enqueue thread if it is not already queued</em>;
<em>possibly block current thread</em>;
                }

<em>Release:</em>
                if (tryRelease(arg))
<em>unblock the first queued thread</em>;

(Shared mode is similar but may involve cascading signals.)

<p id="barging">Because checks in acquire are invoked before enqueuing, a newly acquiring thread may <em>barge</em> ahead of others that are blocked and queued. However, you can, if desired, define tryAcquire and/or tryAcquireShared to disable barging by internally invoking one or more of the inspection methods, thereby providing a <em>fair</em> FIFO acquisition order. In particular, most fair synchronizers can define tryAcquire to return false if #hasQueuedPredecessors (a method specifically designed to be used by fair synchronizers) returns true. Other variations are possible.

Throughput and scalability are generally highest for the default barging (also known as <em>greedy</em>, <em>renouncement</em>, and <em>convoy-avoidance</em>) strategy. While this is not guaranteed to be fair or starvation-free, earlier queued threads are allowed to recontend before later queued threads, and each recontention has an unbiased chance to succeed against incoming threads. Also, while acquires do not &quot;spin&quot; in the usual sense, they may perform multiple invocations of tryAcquire interspersed with other computations before blocking. This gives most of the benefits of spins when exclusive synchronization is only briefly held, without most of the liabilities when it isn't. If so desired, you can augment this by preceding calls to acquire methods with "fast-path" checks, possibly prechecking #hasContended and/or #hasQueuedThreads to only do so if the synchronizer is likely not to be contended.

This class provides an efficient and scalable basis for synchronization in part by specializing its range of use to synchronizers that can rely on int state, acquire, and release parameters, and an internal FIFO wait queue. When this does not suffice, you can build synchronizers from a lower level using java.util.concurrent.atomic atomic classes, your own custom java.util.Queue classes, and LockSupport blocking support.

<h2>Usage Examples</h2>

Here is a non-reentrant mutual exclusion lock class that uses the value zero to represent the unlocked state, and one to represent the locked state. While a non-reentrant lock does not strictly require recording of the current owner thread, this class does so anyway to make usage easier to monitor. It also supports conditions and exposes some instrumentation methods:

{@code
            class Mutex implements Lock, java.io.Serializable {

              // Our internal helper class
              private static class Sync extends AbstractQueuedSynchronizer {
                // Acquires the lock if state is zero
                public boolean tryAcquire(int acquires) {
                  assert acquires == 1; // Otherwise unused
                  if (compareAndSetState(0, 1)) {
                    setExclusiveOwnerThread(Thread.currentThread());
                    return true;
                  }
                  return false;
                }

                // Releases the lock by setting state to zero
                protected boolean tryRelease(int releases) {
                  assert releases == 1; // Otherwise unused
                  if (!isHeldExclusively())
                    throw new IllegalMonitorStateException();
                  setExclusiveOwnerThread(null);
                  setState(0);
                  return true;
                }

                // Reports whether in locked state
                public boolean isLocked() {
                  return getState() != 0;
                }

                public boolean isHeldExclusively() {
                  // a data race, but safe due to out-of-thin-air guarantees
                  return getExclusiveOwnerThread() == Thread.currentThread();
                }

                // Provides a Condition
                public Condition newCondition() {
                  return new ConditionObject();
                }

                // Deserializes properly
                private void readObject(ObjectInputStream s)
                    throws IOException, ClassNotFoundException {
                  s.defaultReadObject();
                  setState(0); // reset to unlocked state
                }
              }

              // The sync object does all the hard work. We just forward to it.
              private final Sync sync = new Sync();

              public void lock()              { sync.acquire(1); }
              public boolean tryLock()        { return sync.tryAcquire(1); }
              public void unlock()            { sync.release(1); }
              public Condition newCondition() { return sync.newCondition(); }
              public boolean isLocked()       { return sync.isLocked(); }
              public boolean isHeldByCurrentThread() {
                return sync.isHeldExclusively();
              }
              public boolean hasQueuedThreads() {
                return sync.hasQueuedThreads();
              }
              public void lockInterruptibly() throws InterruptedException {
                sync.acquireInterruptibly(1);
              }
              public boolean tryLock(long timeout, TimeUnit unit)
                  throws InterruptedException {
                return sync.tryAcquireNanos(1, unit.toNanos(timeout));
              }
            }}

Here is a latch class that is like a java.util.concurrent.CountDownLatch CountDownLatch except that it only requires a single signal to fire. Because a latch is non-exclusive, it uses the shared acquire and release methods.

{@code
            class BooleanLatch {

              private static class Sync extends AbstractQueuedSynchronizer {
                boolean isSignalled() { return getState() != 0; }

                protected int tryAcquireShared(int ignore) {
                  return isSignalled() ? 1 : -1;
                }

                protected boolean tryReleaseShared(int ignore) {
                  setState(1);
                  return true;
                }
              }

              private final Sync sync = new Sync();
              public boolean isSignalled() { return sync.isSignalled(); }
              public void signal()         { sync.releaseShared(1); }
              public void await() throws InterruptedException {
                sync.acquireSharedInterruptibly(1);
              }
            }}

Added in 1.5.

Java documentation for java.util.concurrent.locks.AbstractQueuedSynchronizer.

Portions of this page are modifications based on work created and shared by the Android Open Source Project and used according to terms described in the Creative Commons 2.5 Attribution License.

Constructors

AbstractQueuedSynchronizer()

Creates a new AbstractQueuedSynchronizer instance with initial synchronization state of zero.

AbstractQueuedSynchronizer(IntPtr, JniHandleOwnership)

A constructor used when creating managed representations of JNI objects; called by the runtime.

Properties

Class

Returns the runtime class of this Object.

(Inherited from Object)
ExclusiveOwnerThread

Returns the thread last set by setExclusiveOwnerThread, or null if never set. -or- Sets the thread that currently owns exclusive access.

(Inherited from AbstractOwnableSynchronizer)
ExclusiveQueuedThreads

Returns a collection containing threads that may be waiting to acquire in exclusive mode.

FirstQueuedThread

Returns the first (longest-waiting) thread in the queue, or null if no threads are currently queued.

Handle

The handle to the underlying Android instance.

(Inherited from Object)
HasContended

Queries whether any threads have ever contended to acquire this synchronizer; that is, if an acquire method has ever blocked.

HasQueuedPredecessors

Queries whether any threads have been waiting to acquire longer than the current thread.

HasQueuedThreads

Queries whether any threads are waiting to acquire.

IsHeldExclusively

Returns true if synchronization is held exclusively with respect to the current (calling) thread.

JniIdentityHashCode (Inherited from Object)
JniPeerMembers
PeerReference (Inherited from Object)
QueuedThreads

Returns a collection containing threads that may be waiting to acquire.

QueueLength

Returns an estimate of the number of threads waiting to acquire.

SharedQueuedThreads

Returns a collection containing threads that may be waiting to acquire in shared mode.

State

Returns the current value of synchronization state. -or- Sets the value of synchronization state.

ThresholdClass

This API supports the Mono for Android infrastructure and is not intended to be used directly from your code.

ThresholdType

This API supports the Mono for Android infrastructure and is not intended to be used directly from your code.

Methods

Acquire(Int32)

Acquires in exclusive mode, ignoring interrupts.

AcquireInterruptibly(Int32)

Acquires in exclusive mode, aborting if interrupted.

AcquireShared(Int32)

Acquires in shared mode, ignoring interrupts.

AcquireSharedInterruptibly(Int32)

Acquires in shared mode, aborting if interrupted.

Clone()

Creates and returns a copy of this object.

(Inherited from Object)
CompareAndSetState(Int32, Int32)

Atomically sets synchronization state to the given updated value if the current state value equals the expected value.

Dispose() (Inherited from Object)
Dispose(Boolean) (Inherited from Object)
Equals(Object)

Indicates whether some other object is "equal to" this one.

(Inherited from Object)
GetHashCode()

Returns a hash code value for the object.

(Inherited from Object)
GetWaitingThreads(AbstractQueuedSynchronizer+ConditionObject)

Returns a collection containing those threads that may be waiting on the given condition associated with this synchronizer.

GetWaitQueueLength(AbstractQueuedSynchronizer+ConditionObject)

Returns an estimate of the number of threads waiting on the given condition associated with this synchronizer.

HasWaiters(AbstractQueuedSynchronizer+ConditionObject)

Queries whether any threads are waiting on the given condition associated with this synchronizer.

IsQueued(Thread)

Returns true if the given thread is currently queued.

JavaFinalize()

Called by the garbage collector on an object when garbage collection determines that there are no more references to the object.

(Inherited from Object)
Notify()

Wakes up a single thread that is waiting on this object's monitor.

(Inherited from Object)
NotifyAll()

Wakes up all threads that are waiting on this object's monitor.

(Inherited from Object)
Owns(AbstractQueuedSynchronizer+ConditionObject)

Queries whether the given ConditionObject uses this synchronizer as its lock.

Release(Int32)

Releases in exclusive mode.

ReleaseShared(Int32)

Releases in shared mode.

SetHandle(IntPtr, JniHandleOwnership)

Sets the Handle property.

(Inherited from Object)
ToArray<T>() (Inherited from Object)
ToString()

Returns a string representation of the object.

(Inherited from Object)
TryAcquire(Int32)

Attempts to acquire in exclusive mode.

TryAcquireNanos(Int32, Int64)

Attempts to acquire in exclusive mode, aborting if interrupted, and failing if the given timeout elapses.

TryAcquireShared(Int32)

Attempts to acquire in shared mode.

TryAcquireSharedNanos(Int32, Int64)

Attempts to acquire in shared mode, aborting if interrupted, and failing if the given timeout elapses.

TryRelease(Int32)

Attempts to set the state to reflect a release in exclusive mode.

TryReleaseShared(Int32)

Attempts to set the state to reflect a release in shared mode.

UnregisterFromRuntime() (Inherited from Object)
Wait()

Causes the current thread to wait until it is awakened, typically by being <em>notified</em> or <em>interrupted</em>.

(Inherited from Object)
Wait(Int64, Int32)

Causes the current thread to wait until it is awakened, typically by being <em>notified</em> or <em>interrupted</em>, or until a certain amount of real time has elapsed.

(Inherited from Object)
Wait(Int64)

Causes the current thread to wait until it is awakened, typically by being <em>notified</em> or <em>interrupted</em>, or until a certain amount of real time has elapsed.

(Inherited from Object)

Explicit Interface Implementations

IJavaPeerable.Disposed() (Inherited from Object)
IJavaPeerable.DisposeUnlessReferenced() (Inherited from Object)
IJavaPeerable.Finalized() (Inherited from Object)
IJavaPeerable.JniManagedPeerState (Inherited from Object)
IJavaPeerable.SetJniIdentityHashCode(Int32) (Inherited from Object)
IJavaPeerable.SetJniManagedPeerState(JniManagedPeerStates) (Inherited from Object)
IJavaPeerable.SetPeerReference(JniObjectReference) (Inherited from Object)

Extension Methods

JavaCast<TResult>(IJavaObject)

Performs an Android runtime-checked type conversion.

JavaCast<TResult>(IJavaObject)
GetJniTypeName(IJavaPeerable)

Applies to